JP6114605B2 - Wheel bearing sealing device - Google Patents

Description

  The present invention relates to a sealing device for a wheel bearing that rotatably supports a wheel of an automobile or the like with respect to a suspension device.

  2. Description of the Related Art Conventionally, a wheel bearing device for supporting a wheel of an automobile or the like supports a hub wheel for mounting a wheel rotatably via a double row rolling bearing, and includes a drive wheel and a driven wheel. For structural reasons, an inner ring rotation method is generally used for driving wheels, and an inner ring rotation method and an outer ring rotation method are generally used for driven wheels. Further, the wheel bearing device has a structure called a first generation in which a wheel bearing composed of a double row angular ball bearing or the like is fitted between a knuckle and a hub wheel constituting a suspension device. Second generation structure in which body mounting flange or wheel mounting flange is formed directly on the outer periphery of the member, third generation structure in which one inner rolling surface is directly formed on the outer periphery of the hub wheel, or hub wheel, etc. It is roughly classified into a fourth generation structure in which the inner rolling surface is directly formed on the outer periphery of the outer joint member of the speed universal joint.

  In such a wheel bearing, a sealing device is mounted in order to prevent leakage of grease enclosed in the bearing and to prevent rainwater, dust, and the like from entering from the outside. When the temperature inside the bearing sealed by this sealing device rises, the air in the sealed space may pass through the sealing device and be discharged outside. In this case, after that, when the vehicle stops and the temperature in the sealed space decreases, the pressure in the sealed space becomes negative with respect to the external atmospheric pressure. It may be pressed and adsorbed. This can cause the tip of the seal lip to wear abnormally and shorten its life, generate a noise due to temperature rise, or increase the torque due to high contact surface pressure due to adsorption. is there.

  FIGS. 5 and 6 show a sealing device for a wheel bearing that solves these problems. A wheel bearing 50 shown in FIG. 5 includes an inner member 51, an outer member 52, and double-row balls 53, 53 accommodated between the members 51, 52 so as to roll freely. The inner member 51 includes a hub ring 54 and an inner ring 55 press-fitted into the hub ring 54.

  The hub wheel 54 integrally has a wheel mounting flange 56 for mounting the wheel W and the brake rotor B at one end, and a hub bolt 57 for fixing the wheel at a circumferentially equidistant position of the wheel mounting flange 56 is planted. It is installed. Further, one outer rolling surface 54a and a cylindrical small diameter step portion 54b extending in the axial direction from the inner rolling surface 54a are formed on the outer periphery of the hub wheel 54, and a serration 54c is formed on the inner periphery. Yes. The inner ring 55 is formed with the other inner rolling surface 55 a on the outer periphery, and is press-fitted and fixed to the small diameter step portion 54 b of the hub ring 54.

  The outer member 52 integrally has a vehicle body mounting flange 52b to be attached to the vehicle body (not shown) on the outer periphery, and has a double row facing the inner rolling surfaces 54a and 55a of the inner member 51 on the inner periphery. The outer rolling surfaces 52a and 52a are integrally formed. The double-row balls 53 and 53 are accommodated between the rolling surfaces 52a and 54a and 52a and 55a, and are held by the cages 58 and 58 so as to be freely rollable. In addition, sealing devices 59 and 60 are attached to the opening of the annular space formed between the outer member 52 and the inner member 51, and leakage of lubricating grease sealed inside the bearing, rainwater and Dust and the like are prevented from entering the bearing.

  As shown in an enlarged view in FIG. 6, the sealing device 59 includes a cored bar member 61, an elastic member 62, and a slinger 63. The metal core member 61 and the elastic member 62 are fixed to each other and constitute a seal member 64. The cored bar member 61 is formed in an annular shape and has an L-shaped cross section. The core member 61 includes a cylindrical inner fitting fixing portion 61a and a radially extending portion 61b.

  The slinger 63 is formed in an annular shape, and has a cylindrical outer fitting fixing portion 63a, a flange portion 63b, and a bent extending portion 63c. The flange portion 63b is located axially outward from the radially extending portion 61b of the cored bar member 61, and faces the axial direction via a gap. The bent extending portion 63c extends from the radially outer end of the flange portion 63b to the radially extending portion 61b side in the axial direction, and extends to the external fitting fixing portion 63a side in the radial direction. doing.

  The elastic member 62 is formed in an annular shape, and covers the entire inner peripheral surface of the inner fitting fixing portion 61a and the entire outer end surface in the axial direction of the radially extending portion 61b connected to the inner peripheral surface of the inner fitting fixing portion 61a. It is fixed to cover. The elastic member 62 is made of a rubber material, and has a base 65, an axial lip 66, and a radial lip 67. The axial lip 66 extends from the base portion 65 to the radially inner fitting fixing portion 61a side and to the axially outer side. The end portion of the axial lip 66 overlaps both the flange portion 63b and the bent extension portion 63c in the axial direction.

  The radial lip 67 extends from the base portion 65 to the radially outer fitting fixing portion 63a side and to the axial flange portion 63b side. The radial lip 67 slides on the cylindrical outer peripheral surface of the external fitting fixing portion 63 a of the slinger 63.

  The axial lip 66 of the sealing device 59 operates as follows. That is, when the wheel bearing 50 is in an operating state by driving the vehicle, the axial lip 66 and the flange portion 63b are in contact with each other in the initial driving state, and the axial lip 66 is in contact with the bent extending portion 63c. Located at intervals.

  Thereafter, due to the operation of the vehicle, the temperature inside the bearing becomes high and the atmospheric pressure rises to a certain extent, and due to a difference in atmospheric pressure inside and outside the axial lip 66, the radial lip 66 acting on the axial lip 66 outwards. When the force is increased, the inner space of the axial lip 66 is deformed so as to become larger, away from the flange portion 63b, and comes into contact with the inner peripheral surface 68 of the bent extending portion 63c.

  After that, when the temperature inside the bearing is lowered to some extent due to the stop of the vehicle, the inner lip 66 is deformed so that the space inside the axial lip 66 is reduced by the restoring force of the axial lip 66, and away from the bending extension 63c, It contacts the flange part 63b again.

  In this manner, the axial lip 66 slides on the flange portion 63b or the bent extension portion 63c, and the member on which the axial lip 66 slides is a pressure between the atmospheric pressure of the sealed space sealed by the sealing device 59 and the external atmospheric pressure. Based on the magnitude of the difference, the wear of the axial lip 66 can be suppressed, and the torque caused by the contact surface pressure against the flange portion 63b can be reduced (see, for example, Patent Document 1).

JP 2010-190323 A

  However, in this conventional sealing device 59, the distal end portion of the flange portion 63b of the slinger 63 is bent at an acute angle at a predetermined angle to form the bent extension portion 63c, so the following problems are inherent. . That is, when the slinger 63 is formed by press working, the workability is poor, and therefore the number of work steps increases, and the work cost increases. In addition, it is difficult to ensure the dimensional accuracy of the bent extension portion 63 c, and a stable contact state with the axial lip 66 cannot be obtained.

  Further, when the vehicle travels, the temperature of the bearing rises due to the heat generated by the rolling of the balls 53, the sliding of each lip, and the brake parts from the outside of the bearing, and the pressure inside the bearing rises. When the radial lip 67 has a small squeezing force (tightening force), the gas inside the bearing leaks to the outside. Thereafter, when the bearing returns to room temperature when the vehicle is stopped or the like, the internal pressure decreases, and depending on the dimensional accuracy of the bent extension 63c and the axial lip 66, not only the radial lip 67 but also the axial lip 66 is adsorbed and sealed. The rotational torque of the device 59 may increase.

  The present invention has been made in view of such circumstances, and suppresses the side lip of the pack seal from adsorbing to the slinger, prevents abnormal wear of the side lip and increases in rotational torque, and extends the service life. An object of the present invention is to provide a sealing device for a wheel bearing.

  In order to achieve the object, the invention according to claim 1 of the present invention includes an outer member in which a double row outer rolling surface is integrally formed on the inner periphery, and an outer rolling surface of the double row on the outer periphery. A wheel provided with an inner member in which an inner rolling surface facing the inner member is formed, and a double row rolling element which is accommodated so as to roll between the inner member and the outer member. A wheel bearing sealing device that is mounted on a bearing and seals an opening of an annular space formed between the outer member and the inner member, wherein the sealing device has a substantially L-shaped cross section. Formed by a pack seal composed of an annular seal plate and a slinger arranged opposite to each other, and the seal plate is press-fitted into the inner periphery of the end of the outer member, A cored bar consisting of an inner diameter part extending inward in the radial direction from the end of the fitting part, and integrated with the cored bar by vulcanization bonding A sealing member that is joined, and the slinger includes a cylindrical portion that is press-fitted into the outer diameter of the inner member, and a standing plate portion that extends radially outward from the cylindrical portion, and the sealing member includes: A base that covers the inner peripheral surface of the cored bar, a side lip that is formed so as to be inclined radially outward from the base, and that is in sliding contact with the standing plate portion of the slinger, and a radially inward side on the inner diameter side of the side lip In a sealing device for a wheel bearing having a grease lip formed so as to incline and slide in contact with the cylindrical portion of the slinger, grease is applied in advance to the sliding contact portion between the grease lip and the side lip, and the grease lip An annular tongue piece projecting inward of the bearing is integrally formed at the tip end portion of the shaft, and an annular holding portion for storing the grease is formed.

  As described above, the wheel bearing sealing device is mounted on the wheel bearing and seals the opening of the annular space formed between the outer member and the inner member. A cylindrical fitting portion that is formed of a pack seal made of an annular seal plate and a slinger formed in an L shape and opposed to each other, and the seal plate is press-fitted into the inner periphery of the end of the outer member; A cored bar having an inner diameter part extending radially inward from the end of the fitting part, and a seal member integrally joined to the cored bar by vulcanization adhesion, and the slinger has an outer diameter of the inner member A cylindrical portion that is press-fitted into the cylindrical portion, and a vertical plate portion that extends radially outward from the cylindrical portion, and a seal member that inclines radially outward from the base portion that covers the inner peripheral surface of the cored bar. A side lip that is slidably in contact with the slinger vertical plate, and the side lip In a sealing device for a wheel bearing provided with a grease lip that is formed to incline radially inward in the radial direction and is in sliding contact with the cylindrical portion of the slinger, grease is previously applied to the sliding contact portion of the grease lip and the side lip. In addition, an annular tongue piece projecting inward of the bearing is integrally formed at the tip of the grease lip, and an annular holding portion for storing grease is formed. In addition to preventing the internal flow of the bearing, and if the bearing inside becomes positive pressure due to the increase in running during operation, it prevents the gas inside the bearing from leaking outside due to the grease accumulated in the holding section. The air leakage from the inside of the bearing and the leakage of grease due to the air leakage are suppressed. Therefore, when the inside of the bearing becomes negative pressure due to cooling due to operation shutdown, etc., each lip is prevented from adsorbing to the slinger, preventing abnormal wear of the side lip and increase in rotational torque, and extending the service life. It is possible to provide a sealing device for the illustrated wheel bearing.

  Preferably, as in the invention described in claim 2, the end of the cylindrical portion of the slinger is bent radially outward to form an annular bent portion, and the bent portion and the tongue piece have a slight gap. If the labyrinth seal is configured through the gap, the grease can be stored in the holding portion without flowing.

  Further, if the end surface of the bent portion is formed as a tapered surface that gradually increases in diameter outwardly of the bearing as in the invention described in claim 3, the grease lip is damaged when the seal plate is assembled to the slinger. The bent portion can be overcome along the tapered surface without any problem.

  Further, as in the invention described in claim 4, if the outer diameter on the small diameter side of the tapered surface of the bent portion is formed smaller than the outer diameter of the cylindrical portion of the slinger, the seal plate is assembled to the slinger. At this time, it is possible to prevent the grease lip from coming into contact with the bent portion and being reversed or damaged.

  Further, as in the invention described in claim 5, if the grease applied to the sliding contact portion of each lip is made of at least the same base oil as the grease sealed for lubricating the bearing portion, While preventing the deterioration of properties due to the above, the lip wear is prevented to improve the durability, the friction torque is reduced, and the rotational torque of the sealing device can be reduced.

Further, as in the invention described in claim 6, if the penetration of the grease applied to the sliding contact portion of each lip is set in the range of 260 to 300, the grease is difficult to leak to the outside. At the same time, it becomes easy to apply grease to each lip.

  The wheel bearing sealing device according to the present invention includes an outer member in which a double row outer rolling surface is integrally formed on an inner periphery, and an inner rolling surface that faces the outer surface of the double row on an outer periphery. Is mounted on a wheel bearing comprising: an inner member formed with; and a double-row rolling element that is rotatably accommodated between the rolling surfaces of the inner member and the outer member, A wheel bearing sealing device that seals an opening in an annular space formed between an outer member and an inner member, wherein the sealing devices are formed in a substantially L-shaped cross section and are opposed to each other. A cylindrical seal that is press-fitted into the inner periphery of the end of the outer member, and an end of the fit. A cored bar comprising an inner diameter part extending radially inward, and a seal part integrally joined to the cored bar by vulcanization adhesion And the slinger includes a cylindrical portion that is press-fitted into the outer diameter of the inner member, and a standing plate portion that extends radially outward from the cylindrical portion. A base portion that covers the peripheral surface, a side lip that is formed to be inclined radially outward from the base portion, and a lip that is slidably in contact with the standing plate portion of the slinger, and is formed to be inclined inward in the radial direction on the inner diameter side of the side lip. In the sealing device for a wheel bearing provided with a grease lip that is in sliding contact with the cylindrical portion of the slinger, grease is previously applied to the sliding contact portion between the grease lip and the side lip, and a bearing is provided at the tip of the grease lip. An annular tongue piece projecting inward is formed integrally, and an annular holding portion for storing the grease is formed, so that the grease applied in the initial stage is prevented from flowing into the bearing. In In addition, when the inside of the bearing becomes a positive pressure due to an increase in the operating distance during operation, the grease stored in the holding part prevents the gas inside the bearing from leaking to the outside. As a result, the grease is prevented from leaking. Therefore, when the inside of the bearing becomes negative pressure due to cooling due to operation shutdown, etc., each lip is prevented from adsorbing to the slinger, preventing abnormal wear of the side lip and increase in rotational torque, and extending the service life. It is possible to provide a sealing device for the illustrated wheel bearing.

It is a longitudinal section showing one embodiment of a wheel bearing provided with a sealing device concerning the present invention. (A) is a principal part enlarged view which shows the sealing device of FIG. 1, (b) is a principal part enlarged view of (a). It is a principal part enlarged view which shows the modification of the sealing device of FIG. It is explanatory drawing which shows the assembly state of the sealing device of FIG. It is a longitudinal cross-sectional view which shows the wheel bearing provided with the conventional sealing device. It is a principal part enlarged view which shows the sealing device of FIG.

  An outer member in which a double row outer rolling surface is integrally formed on the inner periphery, an inner member in which an inner rolling surface facing the outer rolling surface of the double row is formed on the outer periphery, and the inner member Mounted on a wheel bearing having a member and a double row rolling element housed in a freely rolling manner between the rolling surfaces of the member and the outer member, and formed between the outer member and the inner member A sealing device for a wheel bearing for sealing an opening portion of an annular space, wherein the sealing device is formed of an annular seal plate and a slinger that have a substantially L-shaped cross section and are arranged to face each other. A cored bar composed of a seal, the seal plate comprising a cylindrical fitting portion press-fitted into the inner periphery of the end portion of the outer member, and an inner diameter portion extending radially inward from the end portion of the fitting portion And a sealing member integrally joined to the cored bar by vulcanization adhesion, and the slinger is A cylindrical portion that is press-fitted into the outer diameter of the material, and a standing plate portion that extends radially outward from the cylindrical portion, and the sealing member has a base that covers the inner peripheral surface of the core metal, and a diameter from the base. A side lip formed to be slanted outward in the direction and slidably contacted with the standing plate portion of the slinger, and a grease formed to be slanted radially inward on the inner diameter side of the side lip and slidably contacted with the cylindrical portion of the slinger In a sealing device for a wheel bearing provided with a slip, grease is preliminarily applied to a sliding contact portion of the grease lip and the side lip, and an annular tongue piece protruding inward of the bearing is integrally formed at a tip portion of the grease lip. And the end of the cylindrical portion of the slinger is bent radially outward to form an annular bent portion, and the bent portion and the tongue piece face each other through a slight gap, and the labyrinth seal Configured and said Annular holding portion for accumulating said grease between the curved portion and the tongue is formed.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
1 is a longitudinal sectional view showing an embodiment of a wheel bearing provided with a sealing device according to the present invention, FIG. 2A is an enlarged view of a main part showing the sealing device of FIG. 1, and FIG. FIG. 3 is an enlarged view of a main part of (a), FIG. 3 is an enlarged view of a main part showing a modification of the sealing device of FIG. 2, and FIG. 4 is an explanatory view showing an assembled state of the sealing device of FIG. In the following description, the side closer to the outer side of the vehicle when assembled to the vehicle is referred to as the outer side (left side in FIG. 1), and the side closer to the center is referred to as the inner side (right side in FIG. 1).

  The wheel bearing 1 shown in FIG. 1 is referred to as the first generation, and an outer ring (outer member) 2 in which double rows of outer rolling surfaces 2a and 2a are integrally formed on the inner periphery, and these double rows on the outer periphery. A pair of inner rings 3 and 3 formed with an inner rolling surface 3a opposite to the outer rolling surfaces 2a and 2a, and a double row rolling accommodated between the rolling surfaces via a cage 4 so as to be freely rollable. And moving bodies (balls) 5 and 5. And it sets in the state in which the small end surface (small-diameter side end surface) 3b of a pair of inner ring | wheels 3 and 3 was faced | matched, and comprises the back row type double row angular contact ball bearing.

  The outer ring 2, the inner ring 3 and the rolling element 5 are made of high carbon chrome steel such as SUJ2, and are hardened in the range of 58 to 64 HRC up to the core part by quenching. In addition, sealing devices 6 and 7 are attached to the opening portion of the annular space formed between the outer ring 2 and the pair of inner rings 3 and 3, and leakage of the lubricating grease sealed inside the bearing to the outside Prevents rainwater and dust from entering the bearing.

  In addition, although what was comprised by the double row angular contact ball bearing which used the ball for the rolling element 5 as the wheel bearing 1 was illustrated here, not only this but the double row tapered roller which used the tapered roller for the rolling element 5 You may be comprised with the ball bearing. Further, the bearing structure is not limited to the illustrated first generation, and may be, for example, a second generation structure having a flange on the outer ring, or an inner rolling surface is directly formed on the outer periphery of the hub ring constituting the inner member. A third generation structure in which the inner ring is fixed to the hub ring, or a fourth generation structure in which the inner raceway surface is directly formed on the outer periphery of the outer joint member of the hub ring and the constant velocity universal joint constituting the inner member. There may be.

  The outer side sealing device 6 is constituted by an integral seal comprising a cored bar 8 press-fitted into the inner circumference of the end of the outer ring 2 and a seal member 9 integrally joined to the cored bar 8 by vulcanization adhesion. Yes. The metal core 8 has a substantially L-shaped cross section formed by press working from an austenitic stainless steel plate (JIS standard SUS304 type or the like) or a cold rolled steel plate (JIS standard SPCC type or the like). On the other hand, the seal member 9 is made of synthetic rubber such as NBR (acrylonitrile-butadiene rubber) and has a bifurcated radial lip that is in sliding contact with the outer diameter of the inner ring 3. The seal member 9 is wrapped around and joined so as to cover the outer surface of the cored bar 8 to form a so-called half-metal structure. Thereby, airtightness can be improved and the inside of a bearing can be protected.

  As the material of the seal member 9, in addition to the exemplified NBR, for example, HNBR (hydrogenated acrylonitrile butadiene rubber), EPDM (ethylene propylene rubber), etc. having excellent heat resistance, heat resistance, chemical resistance, etc. Examples thereof include ACM (polyacrylic rubber), FKM (fluororubber), and silicon rubber, which are excellent in the above.

  As shown in FIG. 2A, the inner side sealing device 7 is a so-called pack comprising an annular seal plate 10 and a slinger 11 which are substantially L-shaped in cross section and arranged to face each other. It constitutes a seal. The seal plate 10 includes a metal core 12 that is press-fitted into the outer ring 2, and a seal member 13 that is integrally vulcanized and bonded to the metal core 12.

  The metal core 12 is formed of a cylindrical fitting portion 12a having a substantially L-shaped cross section formed by pressing from an austenitic stainless steel plate or a cold rolled steel plate and press-fitted into the inner periphery of the end of the outer ring 2. An inner diameter portion 12b extending radially inward from one end portion of the fitting portion 12a is provided. And the front-end | tip part of the fitting part 12a of the metal core 12 is formed thinly, and the seal member 13 wraps around and joins so that this front-end | tip part may be covered, and has comprised what is called a half metal structure.

  The seal member 13 is made of a synthetic rubber such as NBR, a base portion 13a that covers the inner peripheral surface of the fitting portion 12a of the core metal 12, and a pair of side lips 13b that are formed to be inclined radially outward from the base portion 13a. 13c, and a grease lip 13d formed on the inner diameter side of the side lip 13c so as to be inclined toward the inner side of the bearing. Examples of the material for the seal member 13 include HNBR, EPDM, ACM, FKM, or silicon rubber having excellent heat resistance, in addition to the exemplified NBR.

  The slinger 11 is formed from a ferritic stainless steel plate (JIS standard SUS430 series, etc.), an austenitic stainless steel plate, or a cold-rolled steel plate that has been rust-proofed by pressing, and has a substantially L-shaped cross section. The cylindrical portion 11a is press-fitted into the outer diameter of the cylindrical portion 11a and the upright plate portion 11b extends radially outward from the cylindrical portion 11a. Then, the side lips 13b and 13c of the seal member 13 are slidably contacted with the upright plate portion 11b via a predetermined axial shimiro, and the grease lip 13d is slidably contacted with the cylindrical portion 11a via a predetermined radial shimillo. ing.

  The base portion 13a of the seal member 13 is formed to be slightly inclined toward the distal end portion of the fitting portion 12a of the core metal 12, and the outer edge of the standing plate portion 11b of the slinger 11 is formed at this end portion with a slight radial clearance. The labyrinth seal 14 is configured to face each other. Thereby, it is possible to prevent rainwater, dust and the like from entering the bearing from the outside.

  In this embodiment, grease 15 is applied to the pair of side lips 13b and 13c and the grease lip 13d. The grease 15 is made of at least the same base oil as the grease sealed for lubricating the bearing portion. Thereby, while preventing deterioration of properties due to mixing, lip wear is prevented and durability is improved, friction torque is reduced, and rotational torque of the sealing device 7 can be reduced.

In addition, the grease 15 has a base oil kinematic viscosity (40 ° C.) of 20 to 60 mm ² / s, and it is difficult for the grease 15 to leak to the outside. Thus, the penetration is set in the range of 260 to 300.

  The grease 15 to be applied may be different from the grease sealed in the bearing portion. In this case, by setting the base oil kinematic viscosity of the grease 15 to be equal to or lower than the base oil kinematic viscosity of the grease sealed in the bearing portion, the friction torque of the lip can be reduced and the rotational torque can be further reduced.

  Here, the end of the cylindrical portion 11 a of the slinger 11 is bent radially outward to form an annular bent portion 16. On the other hand, an annular tongue piece 17 protruding inward of the bearing is integrally formed at the tip of the grease lip 13d. And this tongue piece 17 and the bending part 16 of the cylindrical part 11a oppose through a slight clearance, the labyrinth seal 18 is comprised, and the holding | maintenance part 19 for storing the grease 15 is formed.

  By adopting such a configuration, when there is no pressure difference inside and outside the bearing, it is possible to prevent the grease 15 initially applied by the holding portion 19 from flowing into the bearing. On the other hand, when the inside of the bearing becomes a positive pressure due to the increase in the operating speed during operation, that is, the internal pressure> the external pressure (atmospheric pressure), the gas inside the bearing leaks to the outside due to the grease 15 stored in the holding portion 19. This prevents air leakage from the inside of the bearing and leakage of grease accompanying this air leakage. Therefore, when the inside of the bearing becomes negative pressure due to cooling due to operation stop or the like, that is, when internal pressure <external pressure, the side lips 13b and 13c are suppressed from adsorbing to the slinger 11, and the side lips 13b and 13c It is possible to provide the sealing device 7 for the wheel bearing 1 that prevents abnormal wear and increase in rotational torque and extends the service life.

  FIG. 3 shows a modification of the above-described sealing device 7 (FIG. 2). This embodiment is basically different from the above-described embodiment except that the configuration of the slinger is partially different, and other parts and parts having the same parts or parts having the same functions are denoted by the same reference numerals. Description is omitted.

  The sealing device 20 constitutes a pack seal composed of an annular seal plate 10 and a slinger 21 which are formed in a substantially L-shaped cross section and are arranged to face each other. The slinger 21 is formed into a substantially L-shaped section by pressing from a ferritic stainless steel plate, an austenitic stainless steel plate, or a cold-rolled steel plate that has been rust-proofed, and is press-fitted into the outer diameter of an inner ring (not shown). A cylindrical portion 21a and a standing plate portion 11b extending radially outward from the cylindrical portion 21a are formed, and an end portion of the cylindrical portion 21a is bent radially outward to form an annular bent portion 22.

  Here, the end surface of the bent portion 22 is formed into a tapered surface that gradually increases in diameter toward the bearing outer side (the standing plate portion 11b side). Then, as shown in FIG. 4, when the dimension on the small diameter side of the taper surface of the bent portion 22 is A, the outer diameter dimension of the cylindrical portion 21a of the slinger 21 is B, and the inner diameter dimension of the grease lip 13d is C, It is set so that <C <B. As a result, when the seal plate 10 is assembled to the slinger 21, the grease lip 13 d can get over the bent portion 22 along the tapered surface without being reversed or damaged by contacting the bent portion 22.

  The embodiment of the present invention has been described above, but the present invention is not limited to such an embodiment, and is merely an example, and various modifications can be made without departing from the scope of the present invention. Of course, the scope of the present invention is indicated by the description of the scope of claims, and further, the equivalent meanings described in the scope of claims and all modifications within the scope of the scope of the present invention are included. Including.

  INDUSTRIAL APPLICABILITY The wheel bearing sealing device according to the present invention can be applied to a first generation, a second generation of an inner ring rotating type, an outer ring rotating type, or a third generation, fourth generation wheel bearing of an inner ring rotating type. .

DESCRIPTION OF SYMBOLS 1 Wheel bearing 2 Outer ring 2a Outer rolling surface 3 Inner ring 3a Inner rolling surface 4 Cage 5 Rolling body 6 Outer side sealing device 7, 20 Inner side sealing device 8, 12 Core metal 9, 13 Seal member 10 Seal Plates 11, 21 Slinger 11a, 21a Cylindrical portion 11b Standing plate portion 12a Fitting portion 12b Inner diameter portion 13a Base portion 13b13c of sealing member Side lip 13d Grease lip 14, 18 Labyrinth seal 15 Grease 16, 22 Bending portion 17 Tongue piece 19 Holding portion 50 Wheel Bearing 51 Inner Member 52 Outer Member 52a Outer Rolling Surface 52b Car Body Side Mounting Flange 53 Ball 54 Hub Ring 54a, 55a Inner Rolling Surface 54b Small Diameter Step 54c Serration 55 Inner Ring 56 Wheel Mounting Flange 57 Hub Bolt 58 Cage 59, 60 Sealing device 61 Core metal member 61a Inner fitting fixing part 61b Radial direction Extension part 62 Elastic member 63 Slinger 63a Outer fitting fixing part 63b Flange part 63c Bending extension part 64 Seal member 65 Base part 66 Axial lip 67 Radial lip 68 Inner peripheral surface B of bending extension part Brake rotor W Wheel

Claims (6)

An outer member in which a double row outer rolling surface is integrally formed on the inner periphery;
An inner member in which an inner rolling surface facing the outer rolling surface of the double row is formed on the outer periphery;
The inner member and the outer member are mounted on a wheel bearing provided with a double row rolling element that is slidably accommodated between the rolling surfaces of the outer member, and the outer member and the inner member A wheel bearing sealing device for sealing an opening of an annular space formed therebetween,
The sealing device is composed of a pack seal composed of an annular seal plate and a slinger that have a substantially L-shaped cross section and are arranged to face each other.
A metal core comprising a cylindrical fitting portion in which the seal plate is press-fitted into the inner periphery of the end portion of the outer member, an inner diameter portion extending radially inward from the end portion of the fitting portion, and the metal core And a sealing member joined together by vulcanization adhesion,
The slinger comprises a cylindrical portion that is press-fitted into the outer diameter of the inner member, and a standing plate portion that extends radially outward from the cylindrical portion,
A base portion that covers the inner peripheral surface of the core metal, a side lip that is formed to be inclined radially outward from the base portion, and that is in sliding contact with the standing plate portion of the slinger; and an inner diameter side of the side lip In a sealing device for a wheel bearing having a grease lip formed so as to be inclined radially inwardly and in sliding contact with the cylindrical portion of the slinger,
Grease is pre-applied to the sliding portion of the grease lip and side lip,
An annular tongue piece projecting inward of the bearing is integrally formed at a tip end portion of the grease lip, and an annular holding portion for storing the grease is formed. .   An end portion of the cylindrical portion of the slinger is bent radially outward to form an annular bent portion, and the bent portion and the tongue piece face each other through a slight gap to constitute a labyrinth seal. Item 2. A wheel bearing sealing device according to Item 1.   The wheel bearing sealing device according to claim 2, wherein an end surface of the bent portion is formed as a tapered surface that gradually increases in diameter toward the outer side of the bearing.   The wheel bearing sealing device according to claim 3, wherein an outer diameter on a small diameter side of the tapered surface of the bent portion is formed to be smaller than an outer diameter of a cylindrical portion of the slinger.   The wheel bearing sealing device according to claim 1, wherein the grease applied to the sliding contact portion of each lip is made of at least the same base oil as the grease sealed for lubricating the bearing portion. The wheel bearing sealing device according to claim 1 or 5, wherein a penetration of grease applied to the sliding contact portion of each lip is set in a range of 260 to 300.

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